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1  <ul><li>  <ul><li>
2  R. Abernathey, D. Ferreira, and A. Klocker, 2013: Diagnostics of eddy  M. Azaneu, R. Kerr, and M. Mata,
3  mixing in a circumpolar channel. Ocean Modelling, submitted.  2014: <a href="http://www.ocean-sci.net/10/923/2014/os-10-923-2014.html">
4    Assessment of the representation of Antarctic Bottom Water properties in the
5    ECCO2 reanalysis.</a> Ocean Sci., 10, 923-946.
6  </li></ul>  </li></ul>
7    
8  <ul><li>  <ul><li>
9  H. Brix, D. Menemenlis, C. Hill, S. Dutkiewicz, O. Jahn, D. Wang, K. Bowman,  M. Buckley, R. Ponte, G. Forget, and P. Heimbach, 2014:
10  and H. Zhang, 2013: Using Green's Functions to initialize and adjust a global,  Low-frequency SST and upper-ocean heat content variability in the North
11  eddying ocean biogeochemistry general circulation model. Ocean Modelling,  Atlantic. J. Clim., 27, 4996-5018.
 submitted.  
12  </li></ul>  </li></ul>
13    
14  <ul><li>  <ul><li>
15  M. Buckley, R. Ponte, G. Forget, and P. Heimbach, 2013:  A. Chaudhuri, R. Ponte, and A. Nguyen, 2014: A comparison of
16  Low-frequency SST and upper-ocean heat content variability in the North  atmospheric reanalysis products for the Arctic Ocean and implications
17  Atlantic. J. Clim., submitted.  for uncertainties in air-sea fluxes, J. Clim., 27, 5411-5421.
18    </li></ul>
19    
20    <ul><li>
21    R. Chen, G. Flerl, and C. Wunsch, 2014:
22    <a href="http://ecco2.org/manuscripts/2014/Chen2014.pdf"> A
23    description of local and nonlocal eddy-mean flow interaction in a
24    global eddy-permitting state estimate. </a> J. Phys. Oceanogr., 44,
25    2336-2352.
26  </li></ul>  </li></ul>
27    
28  <ul><li>  <ul><li>
29  G. Danabasoglu, et al., 2013:  K. Childers, 2014:
30  North Atlantic simulations in Coordinated Ocean-ice Reference Experiments, phase II (CORE-II): Part I: Mean states.  <a href="http://ecco2.org/manuscripts/2015/Childers2014.pdf">
31  Ocean Modelling, submitted.  Circulation and Transport Across the Iceland Faroes Shetland Ridge.</a>
32    Ph.D. Thesis, Marine and Atmospheric Science, Stony Brook University, NY.
33    </li></ul>
34    
35    <ul><li>
36    H. Dail and C. Wunsch, 2014: Dynamical Reconstruction of Upper-Ocean
37    Conditions in the Last Glacial Maximum Atlantic.  J. Clim., 27, 807–823.
38    </ul></li>
39    
40    <ul><li>
41    G. Danabasoglu, et al., 2014: North Atlantic simulations in Coordinated
42    Ocean-ice Reference Experiments, phase II (CORE-II): Part I: Mean
43    states. Ocean Modelling, 73, 76-107.
44  </li></ul>  </li></ul>
45    
46  <ul><li>  <ul><li>
47  V. Dansereau, P. Heimbach, and M. Losch, 2013: Simulation of sub-ice shelf  G. Danabasoglu, R. Curry, P. Heimbach, Y. Kushnir, C. Meinen, R. Msadek,
48    M. Patterson, L. Thompson, S. Yeager, and R. Zhang, 2014: 2013 US AMOC Science
49    Team Annual Report on Progress and Priorities. 162 pp. <a
50    href="https://usclivar.org/sites/default/files/amoc/2014/USAMOC_2013AnnualReport_final.pdf">
51    US CLIVAR Report 2014-4</a>, US CLIVAR Project Office, Washington D.C., 20006.
52    </ul></li>
53    
54    <ul><li>
55    V. Dansereau, P. Heimbach, and M. Losch, 2014: Simulation of sub-ice shelf
56  melt rates in a general circulation model: velocity-dependent transfer and the  melt rates in a general circulation model: velocity-dependent transfer and the
57  role of friction. J. Geophys. Res., submitted.  role of friction.  J. Geophys. Res., 119, 1765-1790.
58    </ul></li>
59    
60    <ul><li>
61    T. Dotto, R. Kerr, M. Mata, M. Azaneu, I. Wainer, E. Fahrbach, and G. Rohardt,
62    2014: <a href="http://www.ocean-sci.net/10/523/2014/os-10-523-2014.html">
63    Assessment of the structure and variability of Weddell Sea water masses in
64    distinct ocean reanalysis products.</a> Ocean Sci., 10, 523-546.
65    </li></ul>
66    
67    <ul><li>
68    B. Dushaw, 2014:
69    <a href="http://scitation.aip.org/content/asa/journal/jasa/136/1/10.1121/1.4881928?aemail=author">
70    Assessing the horizontal refraction of ocean acoustic tomography
71    signals using high-resolution ocean state estimates.</a>
72    Acoust. Soc. Am., 136, 122.
73    </li></ul>
74    
75    <ul><li>
76    B. Dushaw and D. Menemenlis, 2014:
77    <a href="http://ecco2.org/manuscripts/2014/Dushaw2014.pdf">
78    Antipodal acoustic thermometry: 1960, 2004.</a>
79    Deep-Sea Res. I, 86, 1-20.
80  </li></ul>  </li></ul>
81    
82  <ul><li>  <ul><li>
83  B. Dushaw and D. Menemenlis, 2013: Antipodal acoustic thermometry: 1960,  S. Gao, T. Qu, and X. Nie, 2014: Mixed layer salinity budget in the tropical
84  2004. Deep-Sea Rese. I, in press.  Pacific Ocean estimated by a global GCM. J. Geophys. Res., 119, 8255-8270.
85  </li></ul>  </li></ul>
86    
87  <ul><li>  <ul><li>
88  A. Kalmikov and P. Heimbach, 2013: A Hessian-based method for Uncertainty  P. Heimbach, F. Straneo, O. Sergienko, and G. Hamilton, 2014:
89    International workshop on understanding the response of Greenlands
90    marine-terminating glaciers to oceanic and atmospheric forcing: Challenges to
91    improving observations, process understanding and modeling. June 4-7, 2013,
92    Beverly, MA, USA.
93    <a href="http://www.usclivar.org/sites/default/files/documents/2014/2013GRISOWorkshopReport_v2_0.pdf">US
94    CLIVAR Report 2014-1</a>, US CLIVAR Project Office, Washington DC, 20006.
95    </ul></li>
96    
97    <ul><li>
98    A. Kalmikov and P. Heimbach, 2014: A Hessian-based method for Uncertainty
99  Quantification in Global Ocean State Estimation. SIAM J. Scientific Computing  Quantification in Global Ocean State Estimation. SIAM J. Scientific Computing
100  (Special Section on Planet Earth and Big Data), submitted.  (Special Section on Planet Earth and Big Data), 36, S267–S295.
101    </li></ul>
102    
103    <ul><li>
104    J. Liu, K. Bowman, M. Lee, D. Henze, N. Bousserez, H. Brix,
105    G. Collatz, D. Menemenlis, L. Ott, S. Pawson, D. Jones, and R. Nassar,
106    2014: <a href="http://ecco2.org/manuscripts/2014/Liu2014.pdf">
107    Carbon monitoring system flux estimation and attribution: Impact of
108    ACOS-GOSAT XCO2 sampling on the inference of terrestrial biospheric
109    sources and sinks.</a> Tellus B, 66, 22486.
110  </li></ul>  </li></ul>
111    
112  <ul><li>  <ul><li>
113  M. Morlighem, E. Rignot, J. Mouginot, X. Wu, H. Seroussi, E. Larour, and  M. Losch, V. Strass, B. Cisewski, C. Klaas, and R. Bellerby, 2014:
114  J. Paden, 2013: Bed topography of Russell Glacier, Greenland, inferred from  <a href="http://ecco2.org/manuscripts/2014/Losch2014.pdf">
115  mass conservation using Operation IceBridge data. J. Glaciol., submitted.  Ocean state estimation from hydrography and velocity observations
116    during EIFEX with a regional biogeochemical ocean circulation
117    model.</a> J. Mar. Syst., 129, 437-451.
118  </li></ul>  </li></ul>
119    
120  <ul><li>  <ul><li>
121  M. Morlighem, H. Seroussi, E. Larour and E. Rignot, 2013: Inversion of basal  C. Piecuch, I. Fukumori, R. Ponte and O. Wang, 2014: Vertical Structure of
122  friction in Antarctica using exact and incomplete adjoints of a higher-order  Ocean Pressure Variations with Application to Satellite-Gravimetric
123  model, J. Geophys. Res., submitted.  Observations. Journal of Atmospheric and Oceanic Technology, 32, 603-613.
124  </li></ul>  </li></ul>
125    
126  <ul><li>  <ul><li>
127  F. Roquet, C. Wunsch, G. Forget, P. Heimbach, et al., 2013:  C. Piecuch and R. Ponte, 2014: Mechanisms of global mean steric sea
128  On the contribution of seal hydrographic data to the Southern Ocean Observing  level change.  J. Clim., 27, 824-834.
129  System. Proc. Natl. Acad. Sci. USA, submitted.  </li></ul>
130    
131    <ul><li>
132    R. Ponte, and C. Piecuch, 2014: Interannual bottom pressure signals
133    in the Australian-Antarctic and Bellingshausen Basins. J. Phys. Oceanogr.,
134    44, 1456-1465.
135    </li></ul>
136    
137    <ul><li>
138    R. Sciascia, C. Cenedese, D. Nicoli, P. Heimbach, and F. Straneo, 2014: Impact
139    of periodic intermediary flows on submarine melting of a Greenland glacier.
140    J. Geophys. Res., 119, 7078-7098.
141    </ul></li>
142    
143    <ul><li>
144    H. Seroussi, M. Morlighem, E. Rignot, J. Mouginot, E. Larour,
145    M. Schodlok, and A. Khazendar,
146    2014: <a href="http://ecco2.org/manuscripts/2014/Seroussi2014.pdf">
147    Sensitivity of the dynamics of Pine Island Glacier, West Antarctica,
148    to climate forcing for the next 50 years.</a> The Cryosphere, 8,
149    1699-1710.
150    </li></ul>
151    
152    <ul><li>
153    S. Tett, T. Sherwin, A. Shravat, and O. Browne, 2014: How Much Has the North
154    Atlantic Ocean Overturning Circulation Changed in the Last 50 Years? Journal
155    of Climate, 27, 6325-6342.
156    </ul></li>
157    
158    <ul><li>
159    N. Vinogradova,  R. Ponte, I. Fukumori, and O. Wang, 2014:
160    Estimating satellite salinity errors for assimilation of Aquarius and SMOS
161    data into climate models. J. Geophys. Res., 119, 4732-4744.
162  </li></ul>  </li></ul>
163    
164  <ul><li>  <ul><li>
165  G. Spreen, R. Kwok, D. Menemenlis, and A. Nguyen, 2013: Sea ice  B. Webber, A. Matthews, K. Heywood, J. Kaiser and S. Schmidtko, 2014:
166  deformation in a coupled ocean-sea ice model and in satellite remote  Seaglider observations of equatorial Indian Ocean Rossby waves associated with
167  sensing data. J. Geophys. Res., submitted.  the Madden-Julian Oscillation. J. Geophys. Res., 119, 3714-3731.
168  </li></ul>  </li></ul>
169    
170  <ul><li>  <ul><li>
171  C. Wortham and C. Wunsch, 2013: A multi-dimensional spectral description of  C. Wortham and C. Wunsch, 2014: A multi-dimensional spectral description of
172  ocean variability, submitted.  ocean variability, J. Phys. Oceanogr., 44, 944-966.
173  </li></ul>  </li></ul>
174    
175  <ul><li>  <ul><li>
176  C. Wunsch, 2013: Bidecadal thermal changes in the abyssal ocean and the  C. Wunsch and P. Heimbach, 2014: Bidecadal Thermal Changes in the
177  observational challenge, submitted.  Abyssal Ocean. J. Phys. Oceanogr., 44, 2013-2030.
178  </li></ul>  </li></ul>

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